A new cancer fighting technology developed by Basar Bilgicer and Tanyel Kiziltepe, two professors with deep ties to the University of Notre Dame’s Advanced Diagnostics & Therapeutics (AD&T) initiative, is making a rapid and exciting transition to a real-world, commercialized product—one that could increase the effectiveness of cancer medications while lessening their toxic effects and improving patients’ quality of life.

The technology is centered on ligand-targeted liposomes (LTLs), tiny bubble-like particles made from a phospholipid bilayer—the same molecules that comprise cell membranes. The liposomes are more consistent compared to previous liposomes due to the technique used to create the nanoparticles. The team’s innovative format allows the components to be carefully incorporated during liposome synthesis and, in turn, drastically increases uniformity.

Speaking about the research, Bilgicer explained, “Liposomal nanoparticles work by penetrating the gaps that the vasculature around the tumor tissue has, delivering cancer medication selectively to the cancer cells, and leaving healthy tissue unharmed.”

“In addition to this selective delivery to a tumor,” said Bilgicer, “liposomal nanoparticles also include targeting molecules and stealth coating in their design for more efficient tumor targeting, while staying undetectable to the body’s natural defense mechanism, the immune system.”

“The ability to control the design and fabrication of LTLs to this degree opens up new possibilities for the targeted delivery of chemotherapeutics,” added Kiziltepe, who has served as a research assistant professor in AD&T for the past seven years. “It could be especially attractive to pharmaceutical companies who want to create nanoparticle formulations of struggling or patent-expiring drugs.”

“Basar and Tanyel have been with us almost from the beginning,” says Paul Bohn, AD&T’s director, “and have contributed significantly the university’s biomedical research community. We’re thrilled about where this current work is going and the benefit it could have for patients around the world.”